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SHELL AND TUBE HEAT EXCHANGERS
General Description
Shell and Tube Heat Exchangers are one of the most popular types of exchanger due to the flexibility the
designer has to allow for a wide range of pressures and temperatures. There are two main categories of Shell and
Tube exchanger:
1. those that are used in the petrochemical industry which tend to be covered by standards from TEMA,
Tubular Exchanger Manufacturers Association (see TEMA Standards);
2. those that are used in the power industry such as feedwater heaters and power plant condensers.
Regardless of the type of industry the exchanger is to be used in there are a number of common features (see
Condensers).
A shell and tube exchanger consists of a number of tubes mounted inside a cylindrical shell. Figure 1 illustrates a
typical unit that may be found in a petrochemical plant. Two fluids can exchange heat, one fluid flows over the
outside of the tubes while the second fluid flows through the tubes. The fluids can be single or two phase and
can flow in a parallel or a cross/counter flow arrangement.
Figure 1. Shell and tube exchanger.
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The shell and tube exchanger consists of four major parts:
Front Header this is where the fluid enters the tubeside of the exchanger. It is sometimes referred to as
the Stationary Header.
Rear Header this is where the tubeside fluid leaves the exchanger or where it is returned to the front
header in exchangers with multiple tubeside passes.
Tube bundle this comprises of the tubes, tube sheets, baffles and tie rods etc. to hold the bundle
together.
Shell this contains the tube bundle.
The remainder of this section concentrates on exchangers that are covered by the TEMA Standard.
Shell and Tube Exchanger: Geometric Terminology
The main components of a shell and tube exchanger are shown in Figure 2 a, b and c and described in Table 1.
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Figure 2. Type BEM, CFU and AES exchangers. © 1988 by Tubular Exchanger Manufacturers Association.
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Table 1. Shell and tube geometric terminology
1 Stationary (Front) Head Channel 20 Slip-on Backing Flange
2 Stationary (Front) Head Bonnet 21 Floating Tubesheet Skirt
3 Stationary (Front) Head Flange 22 Floating Tubesheet Skirt
4 Channel Cover 23 Packing Box Flange
5 Stationary Head Nozzle 24 Packing
6 Stationary Tubesheet 25 Packing Follower Ring
7 Tubes 26 Lantern Ring
8 Shell 27 Tie Rods and Spacers
9 Shell Cover 28 Transverse Baffles or Support Plates
10 Shell Flange Stationary Head End 29 Impingement Baffle or Plate
11 Shell Flange Rear Head End 30 Longitudinal Baffle
12 Shell Nozzle 31 Pass Partition
13 Shell Cover Flange 32 Vent Connection
14 Expansion Joint 33 Drain Connection
15 Floating Tubesheet 34 Instrument Connection
16 Floating Head Cover 35 Support Saddle
17 Floating Head Flange 36 Lifting Lug
18 Floating Head Backing Device 37 Support Bracket
19 Split Shear Ring
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Tema Designations
The popularity of shell and tube exchangers has resulted in a standard nomenclature being developed for their
designation and use by the Tubular Exchanger Manufactures Association (TEMA). This nomenclature is
defined in terms letters and diagrams. The first letter describes the front header type, the second letter the shell
type and the third letter the rear header type. Figure 2 shows examples of a BEM, CFU, and AES exchangers
while Figure 3 illustrates the full TEMA nomenclature.
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Figure 3. TEMA nomenclature. © 1988 by Tubulare Exchanger Manufacturers Association.
Many combinations of front header, shell and rear header can be made. The most common combinations for an
E-Type Shell are given in Table 2 but other combinations are also used.
Table 2. Shell and tube geometric terminology
Fixed tubesheet exchangers U-tube exchangers Floating head exchangers
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AEL AEU AES
AEM CEU BES
AEN DEU
BEL
BEM
BEN
Essentially there are three main combinations
Fixed tubesheet exchangers
U-tube exchangers
Floating header exchangers
Fixed Tubesheet Exchanger (L, M, and N Type Rear Headers)
In a fixed tubesheet exchanger, the tubesheet is welded to the shell. This results in a simple and economical
construction and the tube bores can be cleaned mechanically or chemically. However, the outside surfaces of the
tubes are inaccessible except to chemical cleaning.
If large temperature differences exist between the shell and tube materials, it may be necessary to incorporate an
expansion bellows in the shell, to eliminate excessive stresses caused by expansion. Such bellows are often a
source of weakness and failure in operation. In circumstances where the consequences of failure are particularly
grave U-Tube or Floating Header units are normally used.
This is the cheapest of all removable bundle designs, but is generally slightly more expensive than a fixed
tubesheet design at low pressures.
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U-Tube Exchangers
In a U-Tube exchanger any of the front header types may be used and the rear header is normally a M-Type.
The U-tubes permit unlimited thermal expansion, the tube bundle can be removed for cleaning and small
bundle to shell clearances can be achieved. However, since internal cleaning of the tubes by mechanical means is
difficult, it is normal only to use this type where the tube side fluids are clean.
Floating Head Exchanger (P, S, T and W Type Rear Headers)
In this type of exchanger the tubesheet at the Rear Header end is not welded to the shell but allowed to move or
float. The tubesheet at the Front Header (tube side fluid inlet end) is of a larger diameter than the shell and is
sealed in a similar manner to that used in the fixed tubesheet design. The tubesheet at the rear header end of the
shell is of slightly smaller diameter than the shell, allowing the bundle to be pulled through the shell. The use of
a floating head means that thermal expansion can be allowed for and the tube bundle can be removed for
cleaning. There are several rear header types that can be used but the S-Type Rear Head is the most popular. A
floating head exchanger is suitable for the rigorous duties associated with high temperatures and pressures but is
more expensive (typically of order of 25% for carbon steel construction) than the equivalent fixed tubesheet
exchanger.
Considering each header and shell type in turn:
A-Type front header
This type of header is easy to repair and replace. It also gives access to the tubes for cleaning or repair without
having to disturb the pipe work. It does however have two seals (one between the tube sheet and header and the
other between the header and the end plate). This increases the risk of leakage and the cost of the header over a
B-Type Front Header.
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B-Type front header
This is the cheapest type of front header. It also is more suitable than the A-Type Front Header for high pressure
duties because the header has only one seal. A disadvantage is that to gain access to the tubes requires disturbance
to the pipe work in order to remove the header.
C-Type front header
This type of header is for high pressure applications (>100 bar). It does allow access to the tube without
disturbing the pipe work but is difficult to repair and replace because the tube bundle is an integral part of the
header.
D-Type front header
This is the most expensive type of front header. It is for very high pressures (> 150 bar). It does allow access to
the tubes without disturbing the pipe work but is difficult to repair and replace because the tube bundle is an
integral part of the header.
N-Type front header
The advantage of this type of header is that the tubes can be accessed without disturbing the pipe work and it is
cheaper than an A-Type Front Header. However, they are difficult to maintain and replace as the header and
tube sheet are an integral part of the shell.
Y-Type front header
Strictly speaking this is not a TEMA designated type but is generally recognized. It can be used as a front or rear
header and is used when the exchanger is to be used in a pipe line. It is cheaper than other types of headers as it
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reduces piping costs. It is mainly used with single tube pass units although with suitable partitioning any odd
number of passes can be allowed.
E-Type shell
This is most commonly used shell type, suitable for most duties and applications. Other shell types only tend to
be used for special duties or applications.
F-Type shell
This is generally used when pure countercurrent flow is required in a two tube side pass unit. This is achieved by
having two shells side passes the two passes being separated by a longitudinal baffle. The main problem with
this type of unit is thermal and hydraulic leakage across this longitudinal baffle unless special precautions are
taken.
G-Type shell
This is used for horizontal thermosyphon reboilers and applications where the shellside pressure drop needs to be
kept small. This is achieved by splitting the shellside flow.
H-Type shell
This is used for similar applications to G-Type Shell but tends to be used when larger units are required.
J-Type shell
This tends to be used when the maximum allowable pressure drop is exceeded in an E-Type Shell even when
double segmental baffles are used. It is also used when tube vibration is a problem. The divided flow on the
shellside reduces the flow velocities over the tubes and hence reduces the pressure drop and the likelihood of
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tube vibration. When there are two inlet nozzles and one outlet nozzle this is sometimes referred to as an I-Type
Shell.
K-Type shell
This is used only for reboilers to provide a large disengagement space in order to minimize shellside liquid carry
over. Alternatively a K-Type Shell may be used as a chiller. In this case the main process is to cool the tube side
fluid by boiling a fluid on the shellside.
X-Type shell
This is used if the maximum shellside pressure drop is exceeded by all other shell and baffle type combinations.
The main applications are shellside condensers and gas coolers.
L-Type rear header
This type of header is for use with fixed tubesheets only, since the tubesheet is welded to the shell and access to
the outside of the tubes is not possible. The main advantages of this type of header are that access can be gained
to the inside of the tubes without having to remove any pipework and the bundle to shell clearances are small.
The main disadvantage is that a bellows or an expansion roll are required to allow for large thermal expansions
and this limits the permitted operating temperature and pressure.
M-Type rear header
This type of header is similar to the L-Type Rear Header but it is slightly cheaper. However, the header has to be
removed to gain access to the inside of the tubes. Again, special measures have to be taken to cope with large
thermal expansions and this limits the permitted operating temperature and pressure.
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N-Type rear header
The advantage of this type of header is that the tubes can be accessed without disturbing the pipe work.
However, they are difficult to maintain and replace since the header and tube sheet are an integral part of the
shell.
P-Type rear header
This is an outside packed floating rear header. It is, in theory, a low cost floating head design which allows access
to the inside of the tubes for cleaning and also allows the bundle to be removed for cleaning. The main problems
with this type of header are:
large bundle to shell clearances required in order to pull the bundle;
it is limited to low pressure nonhazardous fluids, because it is possible for the shellside fluid to leak via
the packing rings;
only small thermal expansions are permitted.
In practice it is not a low cost design, because the shell has to be rolled to small tolerances for the packing to be
effective.
S-Type rear header
This is a floating rear header with backing device. It is the most expensive of the floating head types but does
allow the bundle to be removed and unlimited thermal expansion is possible. It also has smaller shell to bundle
clearances than the other floating head types. However, it is difficult to dismantle for bundle pulling and the
shell diameter and bundle to shell clearances are larger than for fixed head type exchangers.
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T-Type rear header
This is a pull through floating head. It is cheaper and easier to remove the bundle than with the S-Type Rear
Header, but still allows for unlimited thermal expansion. It does, however, have the largest bundle to shell
clearance of all the floating head types and is more expensive than fixed header and U-tube types.
U-tube
This is the cheapest of all removable bundle designs, but is generally slightly more expensive than a fixed
tubesheet design at low pressures. However, it permits unlimited thermal expansion, allows the bundle to be
removed to clean the outside of the tubes, has the tightest bundle to shell clearances and is the simplest design. A
disadvantage of the U-tube design is that it cannot normally have pure counterflow unless an F-Type Shell is
used. Also, U-tube designs are limited to even numbers of tube passes.
W-Type rear header
This is a packed floating tubesheet with lantern ring. It is the cheapest of the floating head designs, allows for
unlimited thermal expansion and allows the tube bundle to be removed for cleaning. The main problems with
this type of head are:
the large bundle to shell clearances required to pull the bundle and;
the limitation to low pressure nonhazardous fluids (because it is possible for both the fluids to leak via
the packing rings).
It is also possible for the shell and tube side fluids to become mixed if leakage occurs.
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Geometric Options
Tube diameter layout and pitch
Tubes may range in diameter from 12.7 mm (0.5 in) to 50.8 mm (2 in), but 19.05 mm (0.75 in) and 25.4 mm
(1 in) are the most common sizes. The tubes are laid out in triangular or square patterns in the tube sheets. See
Figure 4.
Figure 4. Tube layouts.
The square layouts are required where it is necessary to get at the tube surface for mechanical cleaning. The
triangular arrangement allows more tubes in a given space. The tube pitch is the shortest center-to-center
distance between tubes. The tube spacing is given by the tube pitch/tube diameter ratio, which is normally 1.25
or 1.33. Since a square layout is used for cleaning purposes, a minimum gap of 6.35 mm (0.25 in) is allowed
between tubes.
Baffle types
Baffles are installed on the shell side to give a higher heat-transfer rate due to increased turbulence and to
support the tubes thus reducing the chance of damage due to vibration. There are a number of different baffle
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types, which support the tubes and promote flow across the tubes. Figure 5 shows the following baffle
arrangements:
Single Segmental (this is the most common),
Double Segmental (this is used to obtain a lower shellside velocity and pressure drop),
Disc and Doughnut.
Figure 5. Baffle arrangements.
The center-to-center distance between baffles is called the baffle-pitch and this can be adjusted to vary the
crossflow velocity. In practice the baffle pitch is not normally greater than a distance equal to the inside diameter
of the shell or closer than a distance equal to one-fifth the diameter or 50.8 mm (2 in) whichever is greater. In
order to allow the fluid to flow backwards and forwards across the tubes part of the baffle is cut away. The height
of this part is referred to as the baffle-cut and is measured as a percentage of the shell diameter, e.g., 25 per cent
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baffle-cut. The size of the baffle-cut (or baffle window) needs to be considered along with the baffle pitch. It is
normal to size the baffle-cut and baffle pitch to approximately equalize the velocities through the window and in
crossflow, respectively.
There are two main types of baffle which give longitudinal flow:
Orifice Baffle,
Rod Baffle.
In these types of baffle the turbulence is generated as the flow crosses the baffle.
Heat Transfer Enhancements Devices
There are three main types.
Special surfaces
These tend to be used to promote nucleate boiling when the temperature driving force is small.
Tube inserts
These are normally wire wound inserts or twisted tapes. They are normally used with medium to high viscosity
fluids to improve heat transfer by increasing turbulence. There is also some evidence that they reduce fouling. In
order to use these most effectively the exchanger should be designed for their use. This usually entails increasing
the shell diameter, reducing the tube length and the number of tubeside passes in order to allow for the increased
pressure loss characteristics of the devices.
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Extended surfaces
These are used to increase the heat transfer area when a stream has a low heat transfer coefficient. The most
common type is "low fin tubing" where typically the fins are 1.5 mm high at 19 fins per inch. (See also
Augmentation of Heat Transfer.)
Selection Criteria
In many cases the only way of ensuring optimum selection is to do a full design based on several alternative
geometries. In the first instance, however, several important decisions have to be made concerning:
allocation of fluids to the shellside and tubeside;
selection of shell type;
selection of front end header type;
selection of rear end header type;
selection of exchanger geometry.
To a large extent these often depend on each other. For instance, the allocation of a dirty fluid to the shellside
directly affects the selection of exchanger tube layout.
Fluid allocation
When deciding which side to allocate the hot and cold fluids the following need to be taken into account, in
order of priority.
1. Consider any and every safety and reliability aspect and allocate fluids accordingly. Never allocate
hazardous fluids such they are contained by anything other than conventional bolted and gasketted or
welded joints.
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2. Ensure that the allocation of fluids complies with established engineering practices, particularly those laid
down in customer specifications.
3. Having complied with the above, allocate the fluid likely to cause the most severe mechanical cleaning
problems (if any) to the tubeside.
4. If neither of the above are applicable, the allocation of the fluids should be decided only after running
two alternative designs and selecting the cheapest (this is time consuming if hand calculations are used
but programs such as TASC from the Heat Transfer and Fluid Flow Service (HTFS) make this a trivial
task).
Shell selection
E-type shells are the most common. If a single tube pass is used and provided there are more than three baffles,
then near counter-current flow is achieved. If two or more tube passes are used, then it is not possible to obtain
pure countercurrent flow and the log mean temperature difference must be corrected to allow for combined
cocurrent and countercurrent flow using an F-factor.
G-type shells and H shells are normally specified only for horizontal thermosyphon reboilers. J shells and X-type
shells should be selected if the allowable DP cannot be accommodated in a reasonable E-type design. For services
requiring multiple shells with removable bundles, F-type shells can offer significant savings and should always be
considered provided they are not prohibited by customer specifications
Front header selection
The A-type front header is the standard for dirty tubeside fluids and the B-type is the standard for clean tubeside
fluids. The A-type is also preferred by many operators regardless of the cleanliness of the tubeside fluid in case
access to the tubes is required. Do not use other types unless the following considerations apply.
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A C-type head with removable shell should be considered for hazardous tubeside fluids, heavy bundles or
services requiring frequent shellside cleaning. The N-type head is used when hazardous fluids are on the
tubeside. A D-type head or a B-type head welded to the tubesheet is used for high pressure applications. Y-type
heads are only normally used for single tube-pass exchangers when they are installed in line with a pipeline.
Rear header selection
For normal service a Fixed Header (L, M, N-types) can be used provided that there is no overstressing due to
differential expansion and the shellside will not require mechanical cleaning. If thermal expansion is likely a fixed
header with a bellows can be used provided that the shellside fluid is not hazardous, the shellside pressure does
not exceed 35 bar (500 psia) and the shellside will not require mechanical cleaning.
A U-tube unit can be used to overcome thermal expansion problems and allow the bundle to be removed for
cleaning. However, countercurrent flow can only be achieved by using an F-type shell and mechanical cleaning
of the tubeside can be difficult.
An S-type floating head should be used when thermal expansion needs to be allowed for and access to both sides
of the exchanger is required from cleaning. Other rear head types would not normally be considered except for
the special cases.
Selection of Exchanger Geometry
Tube outside diameter
For the process industry, 19.05 mm (3/4") tends to be the most common.
Tube wall thickness
Reference must be made to a recognized pressure vessel code to decide this.
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Tube length
For a given surface area, the longer the tube length the cheaper the exchanger, although a long thin exchanger
may not be feasible.
Tube layout
45 or 90 degree layouts are chosen if mechanical cleaning is required, otherwise a 30 degree layout is often
selected, because it provides a higher heat transfer and hence smaller exchanger.
Tube pitch
The smallest allowable pitch of 1.25 times the tube outside diameter is normally used unless there is a
requirement to use a larger pitch due to mechanical cleaning or tube end welding.
Number of tube passes
This is usually one or an even number (not normally greater than 16). Increasing the number of passes increases
the heat transfer coefficient but care must be taken to ensure that the tube side ρv2 is not greater than about
10,000 kg/m·s2.
Shell diameter
Standard pipe is normally used for shell diameters up to 610 mm (24"). Above this the shell is made from rolled
plate. Typically shell diameters range from 152 mm to 3000 mm (6" to 120").
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Baffle type
Single segmental baffles are used by default but other types are considered if pressure drop constraints or
vibration is a problem.
Baffle spacing
This is decided after trying to balance the desire for increased crossflow velocity and tube support (smaller baffle
pitch) and pressure drop constraints (larger baffle pitch). TEMA provides guidance on the maximum and
minimum baffle pitch.
Baffle cut
This depends on the baffle type but is typically 45% for single segmental baffles and 25% for double segmental
baffles.
Nozzles and impingement
For shellside nozzles the ρv2 should not be greater than about 9000 in kg/m·s2. For tubeside nozzles the
maximum ρv2 should not exceed 2230 kg/m·s2 for noncorrosive, nonabrasive single phase fluids and 740 kg/m·s2
for other fluids. Impingement protection is always required for gases which are corrosive or abrasive, saturated
vapors and two phases mixtures. Shell or bundle entrance or exit areas should be designed such that a ρv2 of
5950 kg/m·s2 is not exceeded.
Materials of Construction
In general, shell and tube exchangers are made of metal, but for specialist applications (e.g., involving strong
acids or pharmaceuticals), other materials such as graphite, plastic and glass may be used.
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Thermal Design
The thermal design of a shell and tube exchanger is an iterative process which is normally carried out using
computer programs from organizations such as the Heat transfer and Fluid Flow Service (HTFS) or Heat
Transfer Research Incorporated (HTRI). However, it is important that the engineer understands the logic
behind the calculation. In order to calculate the heat transfer coefficients and pressure drops, initial decisions
must be made on the sides the fluids are allocated, the front and rear header type, shell type, baffle type, tube
diameter and tube layout. The tube length, shell diameter, baffle pitch and number of tube passes are also
selected and these are normally the main items that are altered during each iteration in order to maximize the
overall heat transfer within specified allowable pressure drops.
The main steps in the calculation are given below together with calculation methods in the open literature:
1. Calculate the shellside flow distribution [Use Bell-Delaware Method, see Hewitt, Shires, and Bott
(1994)].
2. Calculate the shellside heat transfer coefficient (Use Bell- Delaware Method)
3. Calculate tubeside heat transfer coefficient (see, for example, Tubes: Single Phase Heat Transfer In).
4. Calculate tubeside pressure drop (see, for example, Pressure Drop, Single Phase).
5. Calculate wall resistance and overall heat transfer coefficient (see Overall Heat Transfer Coefficient and
Fouling).
6. Calculate mean temperature difference (see Mean Temperature Difference).
7. Calculate area required.
8. Compare area required with area of assumed geometry and allowed tubeside and shellside pressure drop
with calculated values.
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9. Adjust assumed geometry and repeat calculations until Area required is achieved within the allowable
pressure drops.
Books by E. A. D. Saunders [Saunders (1988)] and G. F. Hewitt, G. L. Shires, and T. R. Bott [Hewitt et al.
(1994)] provides a good overview of tubular thermal design methods and example calculations.
Mechanical Design
The mechanical design of a shell and tube heat exchanger provides information on items such as shell thickness,
flange thickness, etc. These are calculated using a pressure vessel design code such as the Boiler and Pressure
Vessel code from ASME (American Society of Mechanical Engineers) and the British Master Pressure Vessel
Standard, BS 5500. ASME is the most commonly used code for heat exchangers and is in 11 sections. Section
VIII (Confined Pressure Vessels) of the code is the most applicable to heat exchangers but Sections II Materials
and Section V Non Destructive Testing are also relevant.
Both ASME and BS5500 are widely used and accepted throughout the world but some countries insist that their
own national codes are used. In order to try and simplify this the International Standards Organization is now
attempting to develop a new internationally recognized code but it is likely to be a some time before this is
accepted.
References:
1. TEMA Seventh Edition. (1988) Tubular Exchanger Manufacturers Association.
2. Saunders, E. A. D. (1988) Heat Exchangers Selection, Design and Construction, Longman Scientific and
Technical.
3. Hewitt, G. F, Shires, G. L., and Bott, T. R. (1994) Process Heat Transfer, CRC Press.
4. Boiler and Pressure Vessel code, ASME (American Society of Mechanical Engineers).